BibTex RIS Cite

A Hybrid Multi-Loop Controlled FACTS-based Smart V2G Battery Chargers

Year 2013, Volume: 3 Issue: 1, 155 - 160, 01.03.2013

Abstract

The paper presents a flexible hybrid FACTS based AC-DC interface scheme with Flexible AC Transmission System Neutral Point Switched Filter Compensator (NPSFC) stabilization scheme developed by the Second Author to improve power quality and energy utilization in future Smart Grid-V2G Electric Vehicle (EV) Fast Battery Charging Stations. The FACTS-based filter compensation scheme proposed in this paper is equipped with a novel multi-loop dynamic error driven time de-scaled controller to enhance power factor, stabilize AC and DC side Common Bus voltages, ensure efficient energy utilization, and halt inrush current especially under fast battery charging modes. The FACTS-based hybrid filter compensator is a pulse width modulated/switched capacitor compensation scheme which uses IGBT/MOSFET switches. In addition, a revised controller is designed to improve the utilization of the DC bus voltage in combination with a Green Plug Filter Compensator (GPFC) device. GPFC device is controlled by a novel dual-loop controller which handles the voltage and current of the DC side of the rectifier. Output signals of the controllers are the inputs for weighted-modified-PID which its output feeds the sinusoidal Pulse Width Modulation (PWM) block. In other words, the control signals of the controllers are used for regulating the PWM (on-off) pulsing sequences. The unified scheme is validated Using MATLAB/SIMULINK toolbox

References

  • K. Marrow, D. Karner, and J. Farancfort, “Plug-in Hybrid Electric vehicle Charging Infrastructure Review”, U.S. Department of Energy- Vehicle Technologies Program, S. Han, S. Han, and K. Sezaki, “Development of an Optimal Vehicle-to-Grid Aggregator for Frequency Regulation”, IEEE Trans., on Smart Grid, 2010, vol. 1, issue 1, 65-72.
  • A. Hajimiragha, CA. Caizares, MW. Fowler, and A. Elkarnel, “Optimal Transition To Plug-In Hybrid Electric Vehicles InOntario, Canada, Considering The Electricity- GridLimitations Industrial Electronics”, IEEE Trans., on Ind. Elec., 2010, vol. 57, issue 2, 690 -701.
  • MG. Egan, DL. O'sullivan, JG. Hayes, MJ. Willers, and CP. Henze, “Power-Factor-Corrected Single-Stage Inductive Charger For Electric Vehicle Batteries”, IEEE Trans., on Ind. Elec., 2007, vol. 54, issue 2, 1217 -26.
  • X. Zhou, G. Wang, S. Lukic, S. Bhattacharya, and A. Huang, “Multi-Function Bi-Directional Battery Charger ForPlug-In Hybrid Electric Vehicle Application”, IEEE Proc., Energy Conversion Congress And Exposition, , 3930 - 6.
  • Sui.Seung-Ki, and Lee. Sang-Joon, “An integral battery charger for four-wheel drive electric vehicle”, IEEE Trans., on Ind. App., 1995 vol. 31, issue 5, 1096-9.
  • M. Fernandez, AJ. Ruddell, N. Vast, J. Esteban, andF. Estela, “Development of a VRLA battery with improved separators and a charge controller for low cost photovoltaic and wind powered installations”, J. Power Sources, 2001, vol. 95, no. 1/2, 135-40.
  • T. Yamazaki, and KI.Muramoto, “An advanced solar charging and battery discharge controller unit”, Renew. Energ, 1998, vol. 15, no. 1, 606-9.
  • J. Woodworth, M. Thomas, J. Stevens, S. Harrington, J. Dunlop, M. Swamy, and D. Leighton,.“Evaluation of the batteries andcharge controllers in small stand-alone photovoltaic Specialists, 1994, 933-45. Proc., Photovoltaic
  • GH. Jung, and GH. Cho,.“New Power Active Filter with Simple Low Cost Structure Without Tuned Filters”, IEEE Pro., Power Electronics Specialists, 1998, vol. 1, 22. MS. El-Mousri, and AM. Sharaf, “Novel
  • STATCOM Controllers for Voltage Stabilization of Wind Energy Scheme”, Int. J. Global Energy, 2006, vol. 26, no. /4 , 382-400.
  • E. Elbakush, and AM. Sharaf, “A Low Impact- Efficient V2H-Battery Charging Scheme for EV-Electric Vehicles”, Int. J. Advanced Renewable Energy Research, , vol. 1, issue. 9, 495-504. M. Elias, K. Nor, N. Rahim, and A. Arof, “Lithium- ion battery charger for high energy application”, in Power Engineering Proceedings. National, pp.283-288. , PECon O. Tremblay, “Experimental validation of a battery dynamic model for EV applications”, World Elec. Vehicle J., vol. 3, 2009.
Year 2013, Volume: 3 Issue: 1, 155 - 160, 01.03.2013

Abstract

References

  • K. Marrow, D. Karner, and J. Farancfort, “Plug-in Hybrid Electric vehicle Charging Infrastructure Review”, U.S. Department of Energy- Vehicle Technologies Program, S. Han, S. Han, and K. Sezaki, “Development of an Optimal Vehicle-to-Grid Aggregator for Frequency Regulation”, IEEE Trans., on Smart Grid, 2010, vol. 1, issue 1, 65-72.
  • A. Hajimiragha, CA. Caizares, MW. Fowler, and A. Elkarnel, “Optimal Transition To Plug-In Hybrid Electric Vehicles InOntario, Canada, Considering The Electricity- GridLimitations Industrial Electronics”, IEEE Trans., on Ind. Elec., 2010, vol. 57, issue 2, 690 -701.
  • MG. Egan, DL. O'sullivan, JG. Hayes, MJ. Willers, and CP. Henze, “Power-Factor-Corrected Single-Stage Inductive Charger For Electric Vehicle Batteries”, IEEE Trans., on Ind. Elec., 2007, vol. 54, issue 2, 1217 -26.
  • X. Zhou, G. Wang, S. Lukic, S. Bhattacharya, and A. Huang, “Multi-Function Bi-Directional Battery Charger ForPlug-In Hybrid Electric Vehicle Application”, IEEE Proc., Energy Conversion Congress And Exposition, , 3930 - 6.
  • Sui.Seung-Ki, and Lee. Sang-Joon, “An integral battery charger for four-wheel drive electric vehicle”, IEEE Trans., on Ind. App., 1995 vol. 31, issue 5, 1096-9.
  • M. Fernandez, AJ. Ruddell, N. Vast, J. Esteban, andF. Estela, “Development of a VRLA battery with improved separators and a charge controller for low cost photovoltaic and wind powered installations”, J. Power Sources, 2001, vol. 95, no. 1/2, 135-40.
  • T. Yamazaki, and KI.Muramoto, “An advanced solar charging and battery discharge controller unit”, Renew. Energ, 1998, vol. 15, no. 1, 606-9.
  • J. Woodworth, M. Thomas, J. Stevens, S. Harrington, J. Dunlop, M. Swamy, and D. Leighton,.“Evaluation of the batteries andcharge controllers in small stand-alone photovoltaic Specialists, 1994, 933-45. Proc., Photovoltaic
  • GH. Jung, and GH. Cho,.“New Power Active Filter with Simple Low Cost Structure Without Tuned Filters”, IEEE Pro., Power Electronics Specialists, 1998, vol. 1, 22. MS. El-Mousri, and AM. Sharaf, “Novel
  • STATCOM Controllers for Voltage Stabilization of Wind Energy Scheme”, Int. J. Global Energy, 2006, vol. 26, no. /4 , 382-400.
  • E. Elbakush, and AM. Sharaf, “A Low Impact- Efficient V2H-Battery Charging Scheme for EV-Electric Vehicles”, Int. J. Advanced Renewable Energy Research, , vol. 1, issue. 9, 495-504. M. Elias, K. Nor, N. Rahim, and A. Arof, “Lithium- ion battery charger for high energy application”, in Power Engineering Proceedings. National, pp.283-288. , PECon O. Tremblay, “Experimental validation of a battery dynamic model for EV applications”, World Elec. Vehicle J., vol. 3, 2009.
There are 11 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Behnam Khaki This is me

Adel M. Sharaf This is me

Publication Date March 1, 2013
Published in Issue Year 2013 Volume: 3 Issue: 1

Cite

APA Khaki, B., & Sharaf, A. M. (2013). A Hybrid Multi-Loop Controlled FACTS-based Smart V2G Battery Chargers. International Journal Of Renewable Energy Research, 3(1), 155-160.
AMA Khaki B, Sharaf AM. A Hybrid Multi-Loop Controlled FACTS-based Smart V2G Battery Chargers. International Journal Of Renewable Energy Research. March 2013;3(1):155-160.
Chicago Khaki, Behnam, and Adel M. Sharaf. “A Hybrid Multi-Loop Controlled FACTS-Based Smart V2G Battery Chargers”. International Journal Of Renewable Energy Research 3, no. 1 (March 2013): 155-60.
EndNote Khaki B, Sharaf AM (March 1, 2013) A Hybrid Multi-Loop Controlled FACTS-based Smart V2G Battery Chargers. International Journal Of Renewable Energy Research 3 1 155–160.
IEEE B. Khaki and A. M. Sharaf, “A Hybrid Multi-Loop Controlled FACTS-based Smart V2G Battery Chargers”, International Journal Of Renewable Energy Research, vol. 3, no. 1, pp. 155–160, 2013.
ISNAD Khaki, Behnam - Sharaf, Adel M. “A Hybrid Multi-Loop Controlled FACTS-Based Smart V2G Battery Chargers”. International Journal Of Renewable Energy Research 3/1 (March 2013), 155-160.
JAMA Khaki B, Sharaf AM. A Hybrid Multi-Loop Controlled FACTS-based Smart V2G Battery Chargers. International Journal Of Renewable Energy Research. 2013;3:155–160.
MLA Khaki, Behnam and Adel M. Sharaf. “A Hybrid Multi-Loop Controlled FACTS-Based Smart V2G Battery Chargers”. International Journal Of Renewable Energy Research, vol. 3, no. 1, 2013, pp. 155-60.
Vancouver Khaki B, Sharaf AM. A Hybrid Multi-Loop Controlled FACTS-based Smart V2G Battery Chargers. International Journal Of Renewable Energy Research. 2013;3(1):155-60.